Chapter 7 Interest Rate Forwards and Futures
Bond Basics U.S. Treasury Bills (<1 year), no coupons, sell at discount Notes (1 10 years), Bonds (10 30 years), coupons, sell at par STRIPS: claim to a single coupon or principal, zero-coupon 7-2
Bond Basics (cont d) Notation rt (t1,t2): interest rate from time t1 to t2 prevailing at time t Pto (t1,t2): price of a bond quoted at t= t0 to be purchased at t=t1 maturing at t= t2 Yield to maturity: percentage increase in dollars earned from the bond 7-3
Bond Basics (cont d) Zero-coupon bonds make a single payment at maturity Table 7.1 Five ways to present equivalent information about default free interest rates. All rates but those in the last column are effective annual rates. One year zero-coupon bond: P(0,1)=0.943396 Pay $0.943396 today to receive $1 at t=1 Yield to maturity (YTM) = 1/0.943396-1 = 0.06 = 6% = r (0,1) Two year zero-coupon bond: P(0,2)=0.881659 YTM=1/0.881659-1=0.134225=(1+r(0,2)) 2 =>r(0,2)=0.065=6.5% 7-4
Bond Basics (cont d) Zero-coupon bond price that pays C t at t: P( 0, t) = Yield curve: graph of annualized bond yields against time Implied forward rates Suppose current one-year rate r(0,1) and two-year rate r(0,2) Current forward rate from year 1 to year 2, r 0 (1,2), must satisfy C [ 1+ r( 0, t)] [1 + r 0 (0,1)][1+ r 0 (1, 2)] = [1 + r 0 (0,2)] 2 t t 7-5
Bond Basics (cont d) Figure 7.1 An investor investing for 2 years has a choice of buying a 2-year zero-coupon bond paying [1+ r0(0, 2)]2 or buying a 1-year bond paying 1+ r0(0, 1) for 1 year, and reinvesting the proceeds at the implied forward rate, r0(1, 2) between years 1 and 2. The implied forward rate makes the investor indifferent between these alternatives. 7-6
Bond Basics (cont d) In general 2 1 [ 1+ r ( t, t )] = 0 1 2 t t [ 1+ r ( 0, t )] 0 2 [ 1+ r ( 0, t )] 0 1 t t 2 1 = P( 0, t1) P( 0, t ) 2 Example 7.1 What are the implied forward rate r 0 (2,3) and forward zerocoupon bond price P 0 (2,3) from year 2 to year 3? (use Table 7.1) P r0 ( 02 23, ) (, ) 1 0. = = 881659 P( 03, ) 0. 816298 1 = 0. 0800705 P( 03, ) 0816298. P0 ( 23, ) = = = 0. 925865 P( 02, ) 0881659. 7-7
Bond Basics (cont d) Coupon bonds The price at time of issue of t of a bond maturing at time T that pays n coupons of size c and maturity payment of $1 B ( tt,, cn, ) = cp( t, t ) + P( t, T) t t i t i= 1 where t i = t + i(t - t)/n For the bond to sell at par the coupon size must be n c = 1 t n i = 1 t P(, t T) P(, t t ) i 7-8
Forward Rate Agreements FRAs are over-the-counter contracts that guarantee a borrowing or lending rate on a given notional principal amount Can be settled at maturity (in arrears) or the initiation of the borrowing or lending transaction FRA settlement in arrears: (r qrtly - r FRA ) x notional principal At the time of borrowing: notional principal x (r qrtly - r FRA )/(1+r qrtly ) FRAs can be synthetically replicated using zero-coupon bonds 7-9
Forward Rate Agreements (cont d) Table 7.3 Investment strategy undertaken at time 0, resulting in net cash flows of $1 on day t, and receiving the implied forward rate, 1 + r(t, t + s) at t + s. This synthetically creates the cash flows from entering into a forward rate agreement on day 0 to lend at day t. 7-10
Forward Rate Agreements (cont d) Table 7.4 Example of synthetic FRA. The transactions in this table are exactly those in Table 7.3, except that all bonds are sold at time t. 7-11
Interest Rate Strips and Stacks Suppose we will borrow $100 million in 6 months for a period of 2 years by rolling over the total every 3 months r 1 =? r 2 =? r 3 =? r 4 =? r 5 =? r 6 =? r 7 =? r 8 =? 0 6 9 12 15 18 21 24 27 $100 $100 $100 $100 $100 $100 $100 $100 7-12
Interest Rate Strips and Stacks (cont d) Two alternatives to hedge the interest rate risk Strip: eight separate $100 million FRAs for each 3-month period Stack: enter 6-month FRA for ~$800 million. Each quarter enter into another FRA decreasing the total by ~$100 each time Strip is the best alternative but requires the existence of FRA far into the future. Stack is more feasible but suffers from basis risk 7-13
Duration Duration is a measure of sensitivity of a bond s price to changes in interest rates Duration $ Change in price for a unit change in yield Change in bond price Unit change in yield divide by 10 (10,000) for change in price given a 1% (1 basis point) change in yield 1 Ci = i + 1 y i= 1 ( 1+ y) n i Modified Duration % Change in price for a unit change in yield 1 1 n Ci 1 Duration = + i i By ( ) 1 y i= 1 ( 1+ y) By ( ) Macaulay Duration Size-weighted average of time until payments 1 + y n Ci 1 Duration = i i By ( ) i= 1 ( 1+ y) By ( ) y: yield per period; to annualize divide by # of payments per year B(y): bond price as a function of yield y 7-14
Duration (cont d) Example 7.4 & 7.5 3-year zero-coupon bond with maturity value of $100 Bond price at YTM of 7.00%: $100/(1.0700 3 )=$81.62979 Bond price at YTM of 7.01%: $100/(1.0701 3 )=$81.60691 Δ=-$0.02288 Example 7.6 Duration: 1 $100 3 = $228. 87 107 107 3.. For a basis point (0.01%) change: -$228.87/10,000=-$0.02289 Macaulay duration: 107. ( $228. 87) = 3000. $81. 62979 3-year annual coupon (6.95485%) bond Macaulay Duration:... ( 1 0 0695485 0 0695485 10695485 ) + ( 2 ) + ( 3 ) = 2. 80915 2 3 10695485. 10695485. 10695485. 7-15
Duration (cont d) What is the new bond price B(y+ε) given a small change ε in yield? Rewrite the Macaulay duration And rearrange D Mac [ By ( + ε) By ( )] 1+ y = ε By ( ) By ( + ε) = By ( ) [ D Mac By ( ) ε ] 1+ y 7-16
Duration (cont d) Example 7.7 Consider the 3-year zero-coupon bond with price $81.63 and yield 7% What will be the price of the bond if the yield were to increase to 7.25%? B(7.25%) = $81.63 ( 3 x $81.63 x 0.0025 / 1.07 ) = $81.058 Using ordinary bond pricing: B(7.25%) = $100 / (1.0725) 3 = $81.060 The formula is only approximate due to the bond s convexity 7-17
Duration (cont d) Duration matching Suppose we own a bond with time to maturity t 1, price B 1, and Macaulay duration D 1 How many (N) of another bond with time to maturity t 2, price B 2, and Macaulay duration D 2 do we need to short to eliminate sensitivity to interest rate changes? The hedge ratio The value of the resulting portfolio with duration zero is B 1 +NB 2 Example 7.8 N DB 1 1( y1)/( 1+ y1) = DB( y)/( 1+ y) 2 2 2 2 We own a 7-year 6% annual coupon bond yielding 7% Want to match its duration by shorting a 10-year, 8% bond yielding 7.5% You can verify that B 1 = $94.611, B 2 =$103.432, D 1 =5.882, and D 2 =7.297 5882. 94. 611/ 107. N = = 0. 7409 7. 297 103. 432 / 1075. 7-18
Duration (cont d) Figure 7.2 Comparison of the value of three bond positions as a function of the yield to maturity: 2.718 10-year zerocoupon bonds, one 10- year bond paying a 10% annual coupon, and one 25-year bond paying a 10% coupon. The duration (D) and convexity (C) of each bond at a yield of 10% are in the legend. 7-19
Treasury Bond/Note Futures Contract Specifications Figure 7.3 Specifications for the Treasury-note futures contract. 7-20
Treasury Bond/Note Futures (cont d) Long T-note futures position is an obligation to buy a 6% bond with maturity between 6.5 and 10 years to maturity The short party is able to choose from various maturities and coupons: the cheapest-to-deliver bond In exchange for the delivery the long pays the short the invoice price. Invoice price = (Futures price x conversion factor) + accrued interest Table 7.5 Prices, yields, and the conversion factor for two bonds. The futures price is 97.583. The short would break even delivering the 8-year 7% bond and lose money delivering the 7-year 5% bond. Both bonds make semiannual coupon payments. Price of the bond if it were to yield 6% 7-21
Repurchase Agreements A repurchase agreement or a repo entails selling a security with an agreement to buy it back at a fixed price The underlying security is held as collateral by the counterparty => A repo is collateralized borrowing Frequently used by securities dealers to finance inventory Speculators and hedge funds also use repos to finance their speculative positions A haircut is charged by the counterparty to account for credit risk 7-22
Chapter 7 Additional Art
Table 7.2 Yields and prices on bills, notes, and bonds issued by the U.S. government, October 12, 2007. Bid and asked yields are reported for bills. Prices for notes, bonds, and strips are ask prices. Note and bond prices are quoted in 32nds (e.g., 100:14 is 100 and 14/32, or 100.4375.) Source: Wall Street Journal Online. 7-24
Equation 7.1 7-25
Equation 7.2 7-26
Equation 7.3 7-27
Equation 7.4 7-28
Equation 7.5 7-29
Equation 7.6 7-30
Equation 7.7 7-31
Equation 7.8 7-32
Equation 7.9 7-33
Equation 7.10 7-34
Equation 7.11 7-35
Equation 7.12 7-36
Equation 7.13 7-37
Equation 7.14 7-38
Equation 7.15 7-39
Equation 7.16 7-40
Equation 7.17 7-41
Equation 7.18 7-42
Equation 7.19 7-43
Table 7.6 Treasury-bill quotations. 7-44
Equation 7.20 7-45